基于细径光纤的海底光缆关键技术研究与验证（特邀）

孙云鹏; 胥国祥; 许人东; 康慧灵; 王畅; 印炜

doi:10.13756/j.gtxyj.2025.250010

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基于细径光纤的海底光缆关键技术研究与验证（特邀）

专题：海洋通信与传感网络 | 更新时间：2025-08-16

- 基于细径光纤的海底光缆关键技术研究与验证（特邀）
- Research and Verification of Key Technologies of Submarine Cable based on Fine Diameter Fiber
- 光通信研究 2025年第4期
- 作者机构：
  
  江苏亨通华海科技股份有限公司，江苏　常熟　215500
- 作者简介：
  
  孙云鹏，工程师。E-mail：756325614@qq.com
- 基金信息：
- DOI：10.13756/j.gtxyj.2025.250010
  中图分类号： TN818
- 收稿日期：2025-01-13，
  
  修回日期：2025-01-14，
  
  纸质出版日期：2025-08-10
- 稿件说明：
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孙云鹏，胥国祥，许人东，等. 基于细径光纤的海底光缆关键技术研究与验证[J]. 光通信研究，2025(4): 250010.

Sun Y P, Xu G X, Xu R D, et al. Research and Verification of Key Technologies of Submarine Cable based on Fine Diameter Fiber[J]. Study on Optical Communications, 2025(4): 250010.
孙云鹏，胥国祥，许人东，等. 基于细径光纤的海底光缆关键技术研究与验证[J]. 光通信研究，2025(4): 250010. DOI： 10.13756/j.gtxyj.2025.250010.

Sun Y P, Xu G X, Xu R D, et al. Research and Verification of Key Technologies of Submarine Cable based on Fine Diameter Fiber[J]. Study on Optical Communications, 2025(4): 250010. DOI： 10.13756/j.gtxyj.2025.250010.

摘要

【目的】

海底光缆作为全球互联互通的关键载体，承载着99%以上的通信数据流量，随着国际通信业务的持续增长和海洋数字经济的蓬勃发展，跨洋通信容量面临着严峻挑战。目前，随着高阶调制、波分复用（WDM）和偏振复用（PDM）等扩容技术的成熟，传统光纤传输容量瓶颈问题日益显现。200 μm细径光纤作为新一代空分复用（SDM）光纤，在满足未来皮比特级容量需求的同时能够降低海底光缆系统单比特成本。

【方法】

文章针对细径光纤关键技术展开研究攻关，结合光纤自身特点建立了细径光纤余长模型，求解了细径光纤海底光缆余长边界条件。同时，利用3因素4水平正交试验设计优化了细径光纤熔接参数，通过定义光纤熔接一次合格率，获得细径光纤最优熔接参数组合。

【结果】

文章最终完成了细径光纤海底光缆成缆关键技术的开发，细径光纤成缆附加衰减低于0.003 dB/km，实现了成缆附加衰减与可靠性寿命的平衡控制，同时控制细径光纤熔接一次合格率在90%以上，满足超长距跨洋通信需求。文章所研制海底光缆通过了国际电信联盟-电信标准分局（ITU-T）G.976建议的海底光缆关键性能试验和5 km深海海试试验验证，光透射性能变化远低于0.05 dB。

【结论】

文章研制的大芯数和低附加损耗细径光纤海底光缆性能指标满足海底光缆通信系统的技术要求，为未来新一代细径光纤海洋通信系统的发展提供了重要技术支撑。

Abstract

【Objective】

Submarine cables

as a key enabler of global connectivity

carry over 99% of the world's communication data traffic. With the continuous growth of international communication services and the vigorous development of the marine digital economy

the capacity for transoceanic communication is facing a severe challenge. Currently

with the maturation of capacity-expansion technologies such as higher-order modulation

Wavelength Division Multiplexing (WDM)

and Polarization Division Multiplexing (PDM)

the bottleneck problem of traditional fiber-optic transmission capacity is becoming increasingly evident. As a new generation of Space Division Multiplexing (SDM) fiber

200 μm fine diameter fiber can meet the future Pbit capacity demand and reduce the per bit cost of submarine optical cable system.

【Methods】

The article focuses on the research and development of key technologies for thin-diameter optical fibers. By leveraging the inherent characteristics of optical fibers

a residual length model for thin-diameter fibers is established

and the boundary conditions for the residual length of thin-diameter fibers in submarine cables are solved. At the same time

the three factor and four level orthogonal experimental design is used to optimize the fusion parameters of fine diameter fiber

and the optimal fusion parameter combination of fine diameter fiber is obtained by defining the one-time qualification rate of fiber fusion.

【Results】

Finally

the development of key technologies for the cabling of fine diameter fiber submarine cable is completed. The additional attenuation of fine diameter fiber cabling is less than 0.003 dB/km

which realizes the balance control between the additional attenuation of cabling and the reliability life. At the same time

the one-time qualification rate of fine diameter fiber fusion is controlled to be more than 90%

meeting the requirements of ultra long-distance transoceanic communication. The developed submarine cable has passed the key performance test of submarine cable recom-mended by International Telecommunication Union-Telecommunication Standardization Sector (ITU-T) G.976 and the 5 km deep sea trial test

and the change of light transmission performance is far less than 0.05 dB.

【Conclusion】

The performance indicators of the high fiber count and low additional attenuation fine diameter fiber submarine cable developed in this paper meet the technical requirements of submarine cable communication systems

providing important technical support for the development of the next generation of fine diameter fiber submarine communication systems.

关键词

Keywords

references

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